Transmission Line Equations

Transmission lines take on many forms in order to accommodate particular applications. All rely on the same basic components - two or more conductors separated by a dielectric (insulator). The physical configuration and properties of all the components determines the characteristic impedance, distortion, transmission speed, and loss.

See a discussion on transmission lines and coaxial connectors.

The following formulas are presented in a compact text format that can be copied and pasted into a spreadsheet or other application.

For the following equations, ε is the dielectric constant (ε = 1 for air)

Two Conductors in Parallel (Unbalanced) Above Ground Plane For D << d, h Z₀= (69/ε^½) log₁₀{(4h/d)[1+(2h/D)²]^-½}	Single Conductor Above Ground Plane For d << h Z₀= (138/ε^½) log₁₀(4h/d)
Two Conductors in Parallel (Balanced) Above Ground Plane For D << d, h₁, h₂ Z₀= (276/ε^½) log₁₀{(2D/d)[1+(D/2h)²]^-½}	Two Conductors in Parallel (Balanced) Different Heights Above Ground Plane For D << d, h₁, h₂ Z₀= (276/ε^½)log₁₀{(2D/d)[1+(D²/4h₁h₂)]^-½}
Single Conductor Between Parallel Ground Planes For d/h << 0.75 Z₀= (138/ε^½) log₁₀(4h/πd)	Two Conductors in Parallel (Balanced) Between Parallel Ground Planes For d << D, h Z₀= (276/ε^½) log₁₀{[4h tanh(πD/2h)]/πd}
Balanced Conductors Between Parallel Ground Planes For d << h Z₀= (276/ε^½) log₁₀(2h/πd)	Two Conductors in Parallel (Balanced) of Unequal Diameters Z₀= (60/ε^½) cosh^-1 (N) N = ½[(4D²/d₁d₂) - (d₁/d₂) - (d₂/d₁)]
Balanced 4-Wire Array For d << D₁, D₂ Z₀= (138/ε^½) log₁₀{(2D₂/d)[1+(D₂/D₁)²]^-½}	Two Conductors in Open Air Z₀= 276 log₁₀(2D/d)
5-Wire Array For d << D Z₀= (173/ε^½) log₁₀(D/0.933d)	Single Conductor in Square Conductive Enclosure For d << D Z₀≈ [138 log₁₀(ρ) +6.48-2.34A-0.48B-0.12C]/ε^½ A = (1+0.405ρ^-4)/(1-0.405ρ^-4) B = (1+0.163ρ^-8)/(1-0.163ρ^-8) C = (1+0.067ρ^-12)/(1-0.067ρ^-12) ρ= D/d
Air Coaxial Cable with Dielectric Supporting Wedge For d << D Z₀≈ [138 log₁₀(D/d)]/[1+(ε-1)(θ/360)]^½) ε = wedge dielectric constant θ= wedge angle in degrees	Two Conductors Inside Shield (sheath return) For d << D, h Z₀= (69/ε^½) log₁₀[(ν/2σ²)(1-σ⁴)] ν = h/d σ = h/D
Balanced Shielded Line For D>>d, h>>d Z₀= (276/ε^½) log₁₀{2ν[(1-σ²)/(1+σ²)]} ν = h/d σ = h/D
Two Conductors in Parallel (Unbalanced) Inside Rectangular Enclosure For d << D, h, w ∞ Z₀= (276/ε^½) {log₁₀[(4h tanh(πD/2h)/πd)- ∑ log₁₀[(1+μ_m²)/(1-ν_m²)]} ^m=1 μ_m=sinh(πD/2h)/cosh(mπw/2h) ν_m=sinh(πD/2h)/sinh(mπw/2h)

Equations appear in "Reference Data for Engineers," Sams Publishing 1993




About RF Cafe
Copyright: 1996 - 2024 Webmaster: Kirt Blattenberger, BSEE - KB3UON
RF Cafe began life in 1996 as "RF Tools" in an AOL screen name web space totaling 2 MB. Its primary purpose was to provide me with ready access to commonly needed formulas and reference material while performing my work as an RF system and circuit design engineer. The World Wide Web (Internet) was largely an unknown entity at the time and bandwidth was a scarce commodity. Dial-up modems blazed along at 14.4 kbps while typing up your telephone line, and a nice lady's voice announced "You've Got Mail" when a new message arrived... All trademarks, copyrights, patents, and other rights of ownership to images and text used on the RF Cafe website are hereby acknowledged. My Hobby Website: AirplanesAndRockets.com Please Support RF Cafe by purchasing my ridiculously low−priced products, all of which I created. RF Cascade Workbook RF & Electronics Symbols for Visio RF & EE Symbols Word RF Workbench (shareware) T-Shirts, Mugs, Cups, Ball Caps, Mouse Pads These Are Available for Free Calculator Workbook Smith Chart™ for Excel